12 files changed, 0 insertions, 1524 deletions

diff --git a/bin/ai/library/graph/aystar/library.nut b/bin/ai/library/graph/aystar/library.nut
deleted file mode 100644
index 1f563961a..000000000
--- a/bin/ai/library/graph/aystar/library.nut
+++ /dev/null
@@ -1,14 +0,0 @@
-/* $Id$ */
-
-class AyStar extends AILibrary {
-	function GetAuthor()      { return "OpenTTD NoAI Developers Team"; }
-	function GetName()        { return "AyStar"; }
-	function GetShortName()   { return "GRA*"; }
-	function GetDescription() { return "An implementation of AyStar"; }
-	function GetVersion()     { return 4; }
-	function GetDate()        { return "2008-06-11"; }
-	function CreateInstance() { return "AyStar"; }
-	function GetCategory()    { return "Graph"; }
-}
-
-RegisterLibrary(AyStar());
diff --git a/bin/ai/library/graph/aystar/main.nut b/bin/ai/library/graph/aystar/main.nut
deleted file mode 100644
index 1999eab14..000000000
--- a/bin/ai/library/graph/aystar/main.nut
+++ /dev/null
@@ -1,238 +0,0 @@
-/* $Id$ */
-
-/**
- * An AyStar implementation.
- *  It solves graphs by finding the fastest route from one point to the other.
- */
-class AyStar
-{
-	_queue_class = import("queue.binary_heap", "", 1);
-	_cost_callback = null;
-	_estimate_callback = null;
-	_neighbours_callback = null;
-	_check_direction_callback = null;
-	_cost_callback_param = null;
-	_estimate_callback_param = null;
-	_neighbours_callback_param = null;
-	_check_direction_callback_param = null;
-	_open = null;
-	_closed = null;
-	_goals = null;
-
-	/**
-	 * @param cost_callback A function that returns the cost of a path. It
-	 *  should accept four parameters, old_path, new_tile, new_direction and
-	 *  cost_callback_param. old_path is an instance of AyStar.Path, and
-	 *  new_node is the new node that is added to that path. It should return
-	 *  the cost of the path including new_node.
-	 * @param estimate_callback A function that returns an estimate from a node
-	 *  to the goal node. It should accept four parameters, tile, direction,
-	 *  goal_nodes and estimate_callback_param. It should return an estimate to
-	 *  the cost from the lowest cost between node and any node out of goal_nodes.
-	 *  Note that this estimate is not allowed to be higher than the real cost
-	 *  between node and any of goal_nodes. A lower value is fine, however the
-	 *  closer it is to the real value, the better the performance.
-	 * @param neighbours_callback A function that returns all neighbouring nodes
-	 *  from a given node. It should accept three parameters, current_path, node
-	 *  and neighbours_callback_param. It should return an array containing all
-	 *  neighbouring nodes, which are an array in the form [tile, direction].
-	 * @param check_direction_callback A function that returns either false or
-	 *  true. It should accept four parameters, tile, existing_direction,
-	 *  new_direction and check_direction_callback_param. It should check
-	 *  if both directions can go together on a single tile.
-	 * @param cost_callback_param This parameters will be passed to cost_callback
-	 *  as fourth parameter. Useful to send is an instance of an object.
-	 * @param estimate_callback_param This parameters will be passed to
-	 *  estimate_callback as fourth parameter. Useful to send is an instance of an
-	 *  object.
-	 * @param neighbours_callback_param This parameters will be passed to
-	 *  neighbours_callback as third parameter. Useful to send is an instance of
-	 *  an object.
-	 * @param check_direction_callback_param This parameters will be passed to
-	 *  check_direction_callback as fourth parameter. Useful to send is an
-	 *  instance of an object.
-	 */
-	constructor(cost_callback, estimate_callback, neighbours_callback, check_direction_callback, cost_callback_param = null,
-	            estimate_callback_param = null, neighbours_callback_param = null, check_direction_callback_param = null)
-	{
-		if (typeof(cost_callback) != "function") throw("'cost_callback' has to be a function-pointer.");
-		if (typeof(estimate_callback) != "function") throw("'estimate_callback' has to be a function-pointer.");
-		if (typeof(neighbours_callback) != "function") throw("'neighbours_callback' has to be a function-pointer.");
-		if (typeof(check_direction_callback) != "function") throw("'check_direction_callback' has to be a function-pointer.");
-
-		this._cost_callback = cost_callback;
-		this._estimate_callback = estimate_callback;
-		this._neighbours_callback = neighbours_callback;
-		this._check_direction_callback = check_direction_callback;
-		this._cost_callback_param = cost_callback_param;
-		this._estimate_callback_param = estimate_callback_param;
-		this._neighbours_callback_param = neighbours_callback_param;
-		this._check_direction_callback_param = check_direction_callback_param;
-	}
-
-	/**
-	 * Initialize a path search between sources and goals.
-	 * @param sources The source nodes. This can an array of either [tile, direction]-pairs or AyStar.Path-instances.
-	 * @param goals The target tiles. This can be an array of either tiles or [tile, next_tile]-pairs.
-	 * @param ignored_tiles An array of tiles that cannot occur in the final path.
-	 */
-	function InitializePath(sources, goals, ignored_tiles = []);
-
-	/**
-	 * Try to find the path as indicated with InitializePath with the lowest cost.
-	 * @param iterations After how many iterations it should abort for a moment.
-	 *  This value should either be -1 for infinite, or > 0. Any other value
-	 *  aborts immediatly and will never find a path.
-	 * @return A route if one was found, or false if the amount of iterations was
-	 *  reached, or null if no path was found.
-	 *  You can call this function over and over as long as it returns false,
-	 *  which is an indication it is not yet done looking for a route.
-	 */
-	function FindPath(iterations);
-};
-
-function AyStar::InitializePath(sources, goals, ignored_tiles = [])
-{
-	if (typeof(sources) != "array" || sources.len() == 0) throw("sources has be a non-empty array.");
-	if (typeof(goals) != "array" || goals.len() == 0) throw("goals has be a non-empty array.");
-
-	this._open = this._queue_class();
-	this._closed = AIList();
-
-	foreach (node in sources) {
-		if (typeof(node) == "array") {
-			if (node[1] <= 0) throw("directional value should never be zero or negative.");
-
-			local new_path = this.Path(null, node[0], node[1], this._cost_callback, this._cost_callback_param);
-			this._open.Insert(new_path, new_path.GetCost() + this._estimate_callback(node[0], node[1], goals, this._estimate_callback_param));
-		} else {
-			this._open.Insert(node, node.GetCost());
-		}
-	}
-
-	this._goals = goals;
-
-	foreach (tile in ignored_tiles) {
-		this._closed.AddItem(tile, ~0);
-	}
-}
-
-function AyStar::FindPath(iterations)
-{
-	if (this._open == null) throw("can't execute over an uninitialized path");
-
-	while (this._open.Count() > 0 && (iterations == -1 || iterations-- > 0)) {
-		/* Get the path with the best score so far */
-		local path = this._open.Pop();
-		local cur_tile = path.GetTile();
-		/* Make sure we didn't already passed it */
-		if (this._closed.HasItem(cur_tile)) {
-			/* If the direction is already on the list, skip this entry */
-			if ((this._closed.GetValue(cur_tile) & path.GetDirection()) != 0) continue;
-
-			/* Scan the path for a possible collision */
-			local scan_path = path.GetParent();
-
-			local mismatch = false;
-			while (scan_path != null) {
-				if (scan_path.GetTile() == cur_tile) {
-					if (!this._check_direction_callback(cur_tile, scan_path.GetDirection(), path.GetDirection(), this._check_direction_callback_param)) {
-						mismatch = true;
-						break;
-					}
-				}
-				scan_path = scan_path.GetParent();
-			}
-			if (mismatch) continue;
-
-			/* Add the new direction */
-			this._closed.SetValue(cur_tile, this._closed.GetValue(cur_tile) | path.GetDirection());
-		} else {
-			/* New entry, make sure we don't check it again */
-			this._closed.AddItem(cur_tile, path.GetDirection());
-		}
-		/* Check if we found the end */
-		foreach (goal in this._goals) {
-			if (typeof(goal) == "array") {
-				if (cur_tile == goal[0]) {
-					local neighbours = this._neighbours_callback(path, cur_tile, this._neighbours_callback_param);
-					foreach (node in neighbours) {
-						if (node[0] == goal[1]) {
-							this._CleanPath();
-							return path;
-						}
-					}
-					continue;
-				}
-			} else {
-				if (cur_tile == goal) {
-					this._CleanPath();
-					return path;
-				}
-			}
-		}
-		/* Scan all neighbours */
-		local neighbours = this._neighbours_callback(path, cur_tile, this._neighbours_callback_param);
-		foreach (node in neighbours) {
-			if (node[1] <= 0) throw("directional value should never be zero or negative.");
-
-			if ((this._closed.GetValue(node[0]) & node[1]) != 0) continue;
-			/* Calculate the new paths and add them to the open list */
-			local new_path = this.Path(path, node[0], node[1], this._cost_callback, this._cost_callback_param);
-			this._open.Insert(new_path, new_path.GetCost() + this._estimate_callback(node[0], node[1], this._goals, this._estimate_callback_param));
-		}
-	}
-
-	if (this._open.Count() > 0) return false;
-	this._CleanPath();
-	return null;
-}
-
-function AyStar::_CleanPath()
-{
-	this._closed = null;
-	this._open = null;
-	this._goals = null;
-}
-
-/**
- * The path of the AyStar algorithm.
- *  It is reversed, that is, the first entry is more close to the goal-nodes
- *  than his GetParent(). You can walk this list to find the whole path.
- *  The last entry has a GetParent() of null.
- */
-class AyStar.Path
-{
-	_prev = null;
-	_tile = null;
-	_direction = null;
-	_cost = null;
-
-	constructor(old_path, new_tile, new_direction, cost_callback, cost_callback_param)
-	{
-		this._prev = old_path;
-		this._tile = new_tile;
-		this._direction = new_direction;
-		this._cost = cost_callback(old_path, new_tile, new_direction, cost_callback_param);
-	};
-
-	/**
-	 * Return the tile where this (partial-)path ends.
-	 */
-	function GetTile() { return this._tile; }
-
-	/**
-	 * Return the direction from which we entered the tile in this (partial-)path.
-	 */
-	function GetDirection() { return this._direction; }
-
-	/**
-	 * Return an instance of this class leading to the previous node.
-	 */
-	function GetParent() { return this._prev; }
-
-	/**
-	 * Return the cost of this (partial-)path from the beginning up to this node.
-	 */
-	function GetCost() { return this._cost; }
-};
diff --git a/bin/ai/library/pathfinder/rail/library.nut b/bin/ai/library/pathfinder/rail/library.nut
deleted file mode 100644
index 8f0dbad08..000000000
--- a/bin/ai/library/pathfinder/rail/library.nut
+++ /dev/null
@@ -1,14 +0,0 @@
-/* $Id$ */
-
-class Rail extends AILibrary {
-	function GetAuthor()      { return "OpenTTD NoAI Developers Team"; }
-	function GetName()        { return "Rail"; }
-	function GetShortName()   { return "PFRL"; }
-	function GetDescription() { return "An implementation of a rail pathfinder"; }
-	function GetVersion()     { return 1; }
-	function GetDate()        { return "2008-09-22"; }
-	function CreateInstance() { return "Rail"; }
-	function GetCategory()    { return "Pathfinder"; }
-}
-
-RegisterLibrary(Rail());
diff --git a/bin/ai/library/pathfinder/rail/main.nut b/bin/ai/library/pathfinder/rail/main.nut
deleted file mode 100644
index 2a9186799..000000000
--- a/bin/ai/library/pathfinder/rail/main.nut
+++ /dev/null
@@ -1,389 +0,0 @@
-/* $Id$ */
-
-/**
- * A Rail Pathfinder.
- */
-class Rail
-{
-	_aystar_class = import("graph.aystar", "", 4);
-	_max_cost = null;              ///< The maximum cost for a route.
-	_cost_tile = null;             ///< The cost for a single tile.
-	_cost_diagonal_tile = null;    ///< The cost for a diagonal tile.
-	_cost_turn = null;             ///< The cost that is added to _cost_tile if the direction changes.
-	_cost_slope = null;            ///< The extra cost if a rail tile is sloped.
-	_cost_bridge_per_tile = null;  ///< The cost per tile of a new bridge, this is added to _cost_tile.
-	_cost_tunnel_per_tile = null;  ///< The cost per tile of a new tunnel, this is added to _cost_tile.
-	_cost_coast = null;            ///< The extra cost for a coast tile.
-	_pathfinder = null;            ///< A reference to the used AyStar object.
-	_max_bridge_length = null;     ///< The maximum length of a bridge that will be build.
-	_max_tunnel_length = null;     ///< The maximum length of a tunnel that will be build.
-
-	cost = null;                   ///< Used to change the costs.
-	_running = null;
-	_goals = null;
-
-	constructor()
-	{
-		this._max_cost = 10000000;
-		this._cost_tile = 100;
-		this._cost_diagonal_tile = 70;
-		this._cost_turn = 50;
-		this._cost_slope = 100;
-		this._cost_bridge_per_tile = 150;
-		this._cost_tunnel_per_tile = 120;
-		this._cost_coast = 20;
-		this._max_bridge_length = 6;
-		this._max_tunnel_length = 6;
-		this._pathfinder = this._aystar_class(this._Cost, this._Estimate, this._Neighbours, this._CheckDirection, this, this, this, this);
-
-		this.cost = this.Cost(this);
-		this._running = false;
-	}
-
-	/**
-	 * Initialize a path search between sources and goals.
-	 * @param sources The source tiles.
-	 * @param goals The target tiles.
-	 * @param ignored_tiles An array of tiles that cannot occur in the final path.
-	 * @see AyStar::InitializePath()
-	 */
-	function InitializePath(sources, goals, ignored_tiles = []) {
-		local nsources = [];
-
-		foreach (node in sources) {
-			local path = this._pathfinder.Path(null, node[1], 0xFF, this._Cost, this);
-			path = this._pathfinder.Path(path, node[0], 0xFF, this._Cost, this);
-			nsources.push(path);
-		}
-		this._goals = goals;
-		this._pathfinder.InitializePath(nsources, goals, ignored_tiles);
-	}
-
-	/**
-	 * Try to find the path as indicated with InitializePath with the lowest cost.
-	 * @param iterations After how many iterations it should abort for a moment.
-	 *  This value should either be -1 for infinite, or > 0. Any other value
-	 *  aborts immediatly and will never find a path.
-	 * @return A route if one was found, or false if the amount of iterations was
-	 *  reached, or null if no path was found.
-	 *  You can call this function over and over as long as it returns false,
-	 *  which is an indication it is not yet done looking for a route.
-	 * @see AyStar::FindPath()
-	 */
-	function FindPath(iterations);
-};
-
-class Rail.Cost
-{
-	_main = null;
-
-	function _set(idx, val)
-	{
-		if (this._main._running) throw("You are not allowed to change parameters of a running pathfinder.");
-
-		switch (idx) {
-			case "max_cost":          this._main._max_cost = val; break;
-			case "tile":              this._main._cost_tile = val; break;
-			case "diagonal_tile":     this._cost_diagonal_tile = val; break;
-			case "turn":              this._main._cost_turn = val; break;
-			case "slope":             this._main._cost_slope = val; break;
-			case "bridge_per_tile":   this._main._cost_bridge_per_tile = val; break;
-			case "tunnel_per_tile":   this._main._cost_tunnel_per_tile = val; break;
-			case "coast":             this._main._cost_coast = val; break;
-			case "max_bridge_length": this._main._max_bridge_length = val; break;
-			case "max_tunnel_length": this._main._max_tunnel_length = val; break;
-			default: throw("the index '" + idx + "' does not exist");
-		}
-
-		return val;
-	}
-
-	function _get(idx)
-	{
-		switch (idx) {
-			case "max_cost":          return this._main._max_cost;
-			case "tile":              return this._main._cost_tile;
-			case "diagonal_tile":     return this._cost_diagonal_tile;
-			case "turn":              return this._main._cost_turn;
-			case "slope":             return this._main._cost_slope;
-			case "bridge_per_tile":   return this._main._cost_bridge_per_tile;
-			case "tunnel_per_tile":   return this._main._cost_tunnel_per_tile;
-			case "coast":             return this._main._cost_coast;
-			case "max_bridge_length": return this._main._max_bridge_length;
-			case "max_tunnel_length": return this._main._max_tunnel_length;
-			default: throw("the index '" + idx + "' does not exist");
-		}
-	}
-
-	constructor(main)
-	{
-		this._main = main;
-	}
-};
-
-function Rail::FindPath(iterations)
-{
-	local test_mode = AITestMode();
-	local ret = this._pathfinder.FindPath(iterations);
-	this._running = (ret == false) ? true : false;
-	if (!this._running && ret != null) {
-		foreach (goal in this._goals) {
-			if (goal[0] == ret.GetTile()) {
-				return this._pathfinder.Path(ret, goal[1], 0, this._Cost, this);
-			}
-		}
-	}
-	return ret;
-}
-
-function Rail::_GetBridgeNumSlopes(end_a, end_b)
-{
-	local slopes = 0;
-	local direction = (end_b - end_a) / AIMap.DistanceManhattan(end_a, end_b);
-	local slope = AITile.GetSlope(end_a);
-	if (!((slope == AITile.SLOPE_NE && direction == 1) || (slope == AITile.SLOPE_SE && direction == -AIMap.GetMapSizeX()) ||
-		(slope == AITile.SLOPE_SW && direction == -1) || (slope == AITile.SLOPE_NW && direction == AIMap.GetMapSizeX()) ||
-		 slope == AITile.SLOPE_N || slope == AITile.SLOPE_E || slope == AITile.SLOPE_S || slope == AITile.SLOPE_W)) {
-		slopes++;
-	}
-
-	local slope = AITile.GetSlope(end_b);
-	direction = -direction;
-	if (!((slope == AITile.SLOPE_NE && direction == 1) || (slope == AITile.SLOPE_SE && direction == -AIMap.GetMapSizeX()) ||
-		(slope == AITile.SLOPE_SW && direction == -1) || (slope == AITile.SLOPE_NW && direction == AIMap.GetMapSizeX()) ||
-		 slope == AITile.SLOPE_N || slope == AITile.SLOPE_E || slope == AITile.SLOPE_S || slope == AITile.SLOPE_W)) {
-		slopes++;
-	}
-	return slopes;
-}
-
-function Rail::_nonzero(a, b)
-{
-	return a != 0 ? a : b;
-}
-
-function Rail::_Cost(path, new_tile, new_direction, self)
-{
-	/* path == null means this is the first node of a path, so the cost is 0. */
-	if (path == null) return 0;
-
-	local prev_tile = path.GetTile();
-
-	/* If the new tile is a bridge / tunnel tile, check whether we came from the other
-	 *  end of the bridge / tunnel or if we just entered the bridge / tunnel. */
-	if (AIBridge.IsBridgeTile(new_tile)) {
-		if (AIBridge.GetOtherBridgeEnd(new_tile) != prev_tile) {
-			local cost = path.GetCost() + self._cost_tile;
-			if (path.GetParent() != null && path.GetParent().GetTile() - prev_tile != prev_tile - new_tile) cost += self._cost_turn;
-			return cost;
-		}
-		return path.GetCost() + AIMap.DistanceManhattan(new_tile, prev_tile) * self._cost_tile + self._GetBridgeNumSlopes(new_tile, prev_tile) * self._cost_slope;
-	}
-	if (AITunnel.IsTunnelTile(new_tile)) {
-		if (AITunnel.GetOtherTunnelEnd(new_tile) != prev_tile) {
-			local cost = path.GetCost() + self._cost_tile;
-			if (path.GetParent() != null && path.GetParent().GetTile() - prev_tile != prev_tile - new_tile) cost += self._cost_turn;
-			return cost;
-		}
-		return path.GetCost() + AIMap.DistanceManhattan(new_tile, prev_tile) * self._cost_tile;
-	}
-
-	/* If the two tiles are more then 1 tile apart, the pathfinder wants a bridge or tunnel
-	 *  to be build. It isn't an existing bridge / tunnel, as that case is already handled. */
-	if (AIMap.DistanceManhattan(new_tile, prev_tile) > 1) {
-		/* Check if we should build a bridge or a tunnel. */
-		local cost = path.GetCost();
-		if (AITunnel.GetOtherTunnelEnd(new_tile) == prev_tile) {
-			cost += AIMap.DistanceManhattan(new_tile, prev_tile) * (self._cost_tile + self._cost_tunnel_per_tile);
-		} else {
-			cost += AIMap.DistanceManhattan(new_tile, prev_tile) * (self._cost_tile + self._cost_bridge_per_tile) + self._GetBridgeNumSlopes(new_tile, prev_tile) * self._cost_slope;
-		}
-		if (path.GetParent() != null && path.GetParent().GetParent() != null &&
-				path.GetParent().GetParent().GetTile() - path.GetParent().GetTile() != max(AIMap.GetTileX(prev_tile) - AIMap.GetTileX(new_tile), AIMap.GetTileY(prev_tile) - AIMap.GetTileY(new_tile)) / AIMap.DistanceManhattan(new_tile, prev_tile)) {
-			cost += self._cost_turn;
-		}
-		return cost;
-	}
-
-	/* Check for a turn. We do this by substracting the TileID of the current
-	 *  node from the TileID of the previous node and comparing that to the
-	 *  difference between the tile before the previous node and the node before
-	 *  that. */
-	local cost = self._cost_tile;
-	if (path.GetParent() != null && AIMap.DistanceManhattan(path.GetParent().GetTile(), prev_tile) == 1 && path.GetParent().GetTile() - prev_tile != prev_tile - new_tile) cost = self._cost_diagonal_tile;
-	if (path.GetParent() != null && path.GetParent().GetParent() != null &&
-			AIMap.DistanceManhattan(new_tile, path.GetParent().GetParent().GetTile()) == 3 &&
-			path.GetParent().GetParent().GetTile() - path.GetParent().GetTile() != prev_tile - new_tile) {
-		cost += self._cost_turn;
-	}
-
-	/* Check if the new tile is a coast tile. */
-	if (AITile.IsCoastTile(new_tile)) {
-		cost += self._cost_coast;
-	}
-
-	/* Check if the last tile was sloped. */
-	if (path.GetParent() != null && !AIBridge.IsBridgeTile(prev_tile) && !AITunnel.IsTunnelTile(prev_tile) &&
-			self._IsSlopedRail(path.GetParent().GetTile(), prev_tile, new_tile)) {
-		cost += self._cost_slope;
-	}
-
-	/* We don't use already existing rail, so the following code is unused. It
-	 *  assigns if no rail exists along the route. */
-	/*
-	if (path.GetParent() != null && !AIRail.AreTilesConnected(path.GetParent().GetTile(), prev_tile, new_tile)) {
-		cost += self._cost_no_existing_rail;
-	}
-	*/
-
-	return path.GetCost() + cost;
-}
-
-function Rail::_Estimate(cur_tile, cur_direction, goal_tiles, self)
-{
-	local min_cost = self._max_cost;
-	/* As estimate we multiply the lowest possible cost for a single tile with
-	 *  with the minimum number of tiles we need to traverse. */
-	foreach (tile in goal_tiles) {
-		local dx = abs(AIMap.GetTileX(cur_tile) - AIMap.GetTileX(tile[0]));
-		local dy = abs(AIMap.GetTileY(cur_tile) - AIMap.GetTileY(tile[0]));
-		min_cost = min(min_cost, min(dx, dy) * self._cost_diagonal_tile * 2 + (max(dx, dy) - min(dx, dy)) * self._cost_tile);
-	}
-	return min_cost;
-}
-
-function Rail::_Neighbours(path, cur_node, self)
-{
-	if (AITile.HasTransportType(cur_node, AITile.TRANSPORT_RAIL)) return [];
-	/* self._max_cost is the maximum path cost, if we go over it, the path isn't valid. */
-	if (path.GetCost() >= self._max_cost) return [];
-	local tiles = [];
-	local offsets = [AIMap.GetTileIndex(0, 1), AIMap.GetTileIndex(0, -1),
-	                 AIMap.GetTileIndex(1, 0), AIMap.GetTileIndex(-1, 0)];
-
-	/* Check if the current tile is part of a bridge or tunnel. */
-	if (AIBridge.IsBridgeTile(cur_node) || AITunnel.IsTunnelTile(cur_node)) {
-		/* We don't use existing rails, so neither existing bridges / tunnels. */
-	} else if (path.GetParent() != null && AIMap.DistanceManhattan(cur_node, path.GetParent().GetTile()) > 1) {
-		local other_end = path.GetParent().GetTile();
-		local next_tile = cur_node + (cur_node - other_end) / AIMap.DistanceManhattan(cur_node, other_end);
-		foreach (offset in offsets) {
-			if (AIRail.BuildRail(cur_node, next_tile, next_tile + offset)) {
-				tiles.push([next_tile, self._GetDirection(other_end, cur_node, next_tile, true)]);
-			}
-		}
-	} else {
-		/* Check all tiles adjacent to the current tile. */
-		foreach (offset in offsets) {
-			local next_tile = cur_node + offset;
-			/* Don't turn back */
-			if (path.GetParent() != null && next_tile == path.GetParent().GetTile()) continue;
-			/* Disallow 90 degree turns */
-			if (path.GetParent() != null && path.GetParent().GetParent() != null &&
-				next_tile - cur_node == path.GetParent().GetParent().GetTile() - path.GetParent().GetTile()) continue;
-			/* We add them to the to the neighbours-list if we can build a rail to
-			 *  them and no rail exists there. */
-			if ((path.GetParent() == null || AIRail.BuildRail(path.GetParent().GetTile(), cur_node, next_tile))) {
-				if (path.GetParent() != null) {
-					tiles.push([next_tile, self._GetDirection(path.GetParent().GetTile(), cur_node, next_tile, false)]);
-				} else {
-					tiles.push([next_tile, self._GetDirection(null, cur_node, next_tile, false)]);
-				}
-			}
-		}
-		if (path.GetParent() != null && path.GetParent().GetParent() != null) {
-			local bridges = self._GetTunnelsBridges(path.GetParent().GetTile(), cur_node, self._GetDirection(path.GetParent().GetParent().GetTile(), path.GetParent().GetTile(), cur_node, true));
-			foreach (tile in bridges) {
-				tiles.push(tile);
-			}
-		}
-	}
-	return tiles;
-}
-
-function Rail::_CheckDirection(tile, existing_direction, new_direction, self)
-{
-	return false;
-}
-
-function Rail::_dir(from, to)
-{
-	if (from - to == 1) return 0;
-	if (from - to == -1) return 1;
-	if (from - to == AIMap.GetMapSizeX()) return 2;
-	if (from - to == -AIMap.GetMapSizeX()) return 3;
-	throw("Shouldn't come here in _dir");
-}
-
-function Rail::_GetDirection(pre_from, from, to, is_bridge)
-{
-	if (is_bridge) {
-		if (from - to == 1) return 1;
-		if (from - to == -1) return 2;
-		if (from - to == AIMap.GetMapSizeX()) return 4;
-		if (from - to == -AIMap.GetMapSizeX()) return 8;
-	}
-	return 1 << (4 + (pre_from == null ? 0 : 4 * this._dir(pre_from, from)) + this._dir(from, to));
-}
-
-/**
- * Get a list of all bridges and tunnels that can be build from the
- *  current tile. Bridges will only be build starting on non-flat tiles
- *  for performance reasons. Tunnels will only be build if no terraforming
- *  is needed on both ends.
- */
-function Rail::_GetTunnelsBridges(last_node, cur_node, bridge_dir)
-{
-	local slope = AITile.GetSlope(cur_node);
-	if (slope == AITile.SLOPE_FLAT && AITile.IsBuildable(cur_node + (cur_node - last_node))) return [];
-	local tiles = [];
-
-	for (local i = 2; i < this._max_bridge_length; i++) {
-		local bridge_list = AIBridgeList_Length(i + 1);
-		local target = cur_node + i * (cur_node - last_node);
-		if (!bridge_list.IsEmpty() && AIBridge.BuildBridge(AIVehicle.VT_RAIL, bridge_list.Begin(), cur_node, target)) {
-			tiles.push([target, bridge_dir]);
-		}
-	}
-
-	if (slope != AITile.SLOPE_SW && slope != AITile.SLOPE_NW && slope != AITile.SLOPE_SE && slope != AITile.SLOPE_NE) return tiles;
-	local other_tunnel_end = AITunnel.GetOtherTunnelEnd(cur_node);
-	if (!AIMap.IsValidTile(other_tunnel_end)) return tiles;
-
-	local tunnel_length = AIMap.DistanceManhattan(cur_node, other_tunnel_end);
-	local prev_tile = cur_node + (cur_node - other_tunnel_end) / tunnel_length;
-	if (AITunnel.GetOtherTunnelEnd(other_tunnel_end) == cur_node && tunnel_length >= 2 &&
-			prev_tile == last_node && tunnel_length < _max_tunnel_length && AITunnel.BuildTunnel(AIVehicle.VT_RAIL, cur_node)) {
-		tiles.push([other_tunnel_end, bridge_dir]);
-	}
-	return tiles;
-}
-
-function Rail::_IsSlopedRail(start, middle, end)
-{
-	local NW = 0; // Set to true if we want to build a rail to / from the north-west
-	local NE = 0; // Set to true if we want to build a rail to / from the north-east
-	local SW = 0; // Set to true if we want to build a rail to / from the south-west
-	local SE = 0; // Set to true if we want to build a rail to / from the south-east
-
-	if (middle - AIMap.GetMapSizeX() == start || middle - AIMap.GetMapSizeX() == end) NW = 1;
-	if (middle - 1 == start || middle - 1 == end) NE = 1;
-	if (middle + AIMap.GetMapSizeX() == start || middle + AIMap.GetMapSizeX() == end) SE = 1;
-	if (middle + 1 == start || middle + 1 == end) SW = 1;
-
-	/* If there is a turn in the current tile, it can't be sloped. */
-	if ((NW || SE) && (NE || SW)) return false;
-
-	local slope = AITile.GetSlope(middle);
-	/* A rail on a steep slope is always sloped. */
-	if (AITile.IsSteepSlope(slope)) return true;
-
-	/* If only one corner is raised, the rail is sloped. */
-	if (slope == AITile.SLOPE_N || slope == AITile.SLOPE_W) return true;
-	if (slope == AITile.SLOPE_S || slope == AITile.SLOPE_E) return true;
-
-	if (NW && (slope == AITile.SLOPE_NW || slope == AITile.SLOPE_SE)) return true;
-	if (NE && (slope == AITile.SLOPE_NE || slope == AITile.SLOPE_SW)) return true;
-
-	return false;
-}
diff --git a/bin/ai/library/pathfinder/road/library.nut b/bin/ai/library/pathfinder/road/library.nut
deleted file mode 100644
index 727cdb9b0..000000000
--- a/bin/ai/library/pathfinder/road/library.nut
+++ /dev/null
@@ -1,14 +0,0 @@
-/* $Id$ */
-
-class Road extends AILibrary {
-	function GetAuthor()      { return "OpenTTD NoAI Developers Team"; }
-	function GetName()        { return "Road"; }
-	function GetShortName()   { return "PFRO"; }
-	function GetDescription() { return "An implementation of a road pathfinder"; }
-	function GetVersion()     { return 3; }
-	function GetDate()        { return "2008-06-18"; }
-	function CreateInstance() { return "Road"; }
-	function GetCategory()    { return "Pathfinder"; }
-}
-
-RegisterLibrary(Road());
diff --git a/bin/ai/library/pathfinder/road/main.nut b/bin/ai/library/pathfinder/road/main.nut
deleted file mode 100644
index 9c5564656..000000000
--- a/bin/ai/library/pathfinder/road/main.nut
+++ /dev/null
@@ -1,363 +0,0 @@
-/* $Id$ */
-
-/**
- * A Road Pathfinder.
- *  This road pathfinder tries to find a buildable / existing route for
- *  road vehicles. You can changes the costs below using for example
- *  roadpf.cost.turn = 30. Note that it's not allowed to change the cost
- *  between consecutive calls to FindPath. You can change the cost before
- *  the first call to FindPath and after FindPath has returned an actual
- *  route. To use only existing roads, set cost.no_existing_road to
- *  cost.max_cost.
- */
-class Road
-{
-	_aystar_class = import("graph.aystar", "", 4);
-	_max_cost = null;              ///< The maximum cost for a route.
-	_cost_tile = null;             ///< The cost for a single tile.
-	_cost_no_existing_road = null; ///< The cost that is added to _cost_tile if no road exists yet.
-	_cost_turn = null;             ///< The cost that is added to _cost_tile if the direction changes.
-	_cost_slope = null;            ///< The extra cost if a road tile is sloped.
-	_cost_bridge_per_tile = null;  ///< The cost per tile of a new bridge, this is added to _cost_tile.
-	_cost_tunnel_per_tile = null;  ///< The cost per tile of a new tunnel, this is added to _cost_tile.
-	_cost_coast = null;            ///< The extra cost for a coast tile.
-	_pathfinder = null;            ///< A reference to the used AyStar object.
-	_max_bridge_length = null;     ///< The maximum length of a bridge that will be build.
-	_max_tunnel_length = null;     ///< The maximum length of a tunnel that will be build.
-
-	cost = null;                   ///< Used to change the costs.
-	_running = null;
-
-	constructor()
-	{
-		this._max_cost = 10000000;
-		this._cost_tile = 100;
-		this._cost_no_existing_road = 40;
-		this._cost_turn = 100;
-		this._cost_slope = 200;
-		this._cost_bridge_per_tile = 150;
-		this._cost_tunnel_per_tile = 120;
-		this._cost_coast = 20;
-		this._max_bridge_length = 10;
-		this._max_tunnel_length = 20;
-		this._pathfinder = this._aystar_class(this._Cost, this._Estimate, this._Neighbours, this._CheckDirection, this, this, this, this);
-
-		this.cost = this.Cost(this);
-		this._running = false;
-	}
-
-	/**
-	 * Initialize a path search between sources and goals.
-	 * @param sources The source tiles.
-	 * @param goals The target tiles.
-	 * @see AyStar::InitializePath()
-	 */
-	function InitializePath(sources, goals) {
-		local nsources = [];
-
-		foreach (node in sources) {
-			nsources.push([node, 0xFF]);
-		}
-		this._pathfinder.InitializePath(nsources, goals);
-	}
-
-	/**
-	 * Try to find the path as indicated with InitializePath with the lowest cost.
-	 * @param iterations After how many iterations it should abort for a moment.
-	 *  This value should either be -1 for infinite, or > 0. Any other value
-	 *  aborts immediatly and will never find a path.
-	 * @return A route if one was found, or false if the amount of iterations was
-	 *  reached, or null if no path was found.
-	 *  You can call this function over and over as long as it returns false,
-	 *  which is an indication it is not yet done looking for a route.
-	 * @see AyStar::FindPath()
-	 */
-	function FindPath(iterations);
-};
-
-class Road.Cost
-{
-	_main = null;
-
-	function _set(idx, val)
-	{
-		if (this._main._running) throw("You are not allowed to change parameters of a running pathfinder.");
-
-		switch (idx) {
-			case "max_cost":          this._main._max_cost = val; break;
-			case "tile":              this._main._cost_tile = val; break;
-			case "no_existing_road":  this._main._cost_no_existing_road = val; break;
-			case "turn":              this._main._cost_turn = val; break;
-			case "slope":             this._main._cost_slope = val; break;
-			case "bridge_per_tile":   this._main._cost_bridge_per_tile = val; break;
-			case "tunnel_per_tile":   this._main._cost_tunnel_per_tile = val; break;
-			case "coast":             this._main._cost_coast = val; break;
-			case "max_bridge_length": this._main._max_bridge_length = val; break;
-			case "max_tunnel_length": this._main._max_tunnel_length = val; break;
-			default: throw("the index '" + idx + "' does not exist");
-		}
-
-		return val;
-	}
-
-	function _get(idx)
-	{
-		switch (idx) {
-			case "max_cost":          return this._main._max_cost;
-			case "tile":              return this._main._cost_tile;
-			case "no_existing_road":  return this._main._cost_no_existing_road;
-			case "turn":              return this._main._cost_turn;
-			case "slope":             return this._main._cost_slope;
-			case "bridge_per_tile":   return this._main._cost_bridge_per_tile;
-			case "tunnel_per_tile":   return this._main._cost_tunnel_per_tile;
-			case "coast":             return this._main._cost_coast;
-			case "max_bridge_length": return this._main._max_bridge_length;
-			case "max_tunnel_length": return this._main._max_tunnel_length;
-			default: throw("the index '" + idx + "' does not exist");
-		}
-	}
-
-	constructor(main)
-	{
-		this._main = main;
-	}
-};
-
-function Road::FindPath(iterations)
-{
-	local test_mode = AITestMode();
-	local ret = this._pathfinder.FindPath(iterations);
-	this._running = (ret == false) ? true : false;
-	return ret;
-}
-
-function Road::_GetBridgeNumSlopes(end_a, end_b)
-{
-	local slopes = 0;
-	local direction = (end_b - end_a) / AIMap.DistanceManhattan(end_a, end_b);
-	local slope = AITile.GetSlope(end_a);
-	if (!((slope == AITile.SLOPE_NE && direction == 1) || (slope == AITile.SLOPE_SE && direction == -AIMap.GetMapSizeX()) ||
-		(slope == AITile.SLOPE_SW && direction == -1) || (slope == AITile.SLOPE_NW && direction == AIMap.GetMapSizeX()) ||
-		 slope == AITile.SLOPE_N || slope == AITile.SLOPE_E || slope == AITile.SLOPE_S || slope == AITile.SLOPE_W)) {
-		slopes++;
-	}
-
-	local slope = AITile.GetSlope(end_b);
-	direction = -direction;
-	if (!((slope == AITile.SLOPE_NE && direction == 1) || (slope == AITile.SLOPE_SE && direction == -AIMap.GetMapSizeX()) ||
-		(slope == AITile.SLOPE_SW && direction == -1) || (slope == AITile.SLOPE_NW && direction == AIMap.GetMapSizeX()) ||
-		 slope == AITile.SLOPE_N || slope == AITile.SLOPE_E || slope == AITile.SLOPE_S || slope == AITile.SLOPE_W)) {
-		slopes++;
-	}
-	return slopes;
-}
-
-function Road::_Cost(path, new_tile, new_direction, self)
-{
-	/* path == null means this is the first node of a path, so the cost is 0. */
-	if (path == null) return 0;
-
-	local prev_tile = path.GetTile();
-
-	/* If the new tile is a bridge / tunnel tile, check whether we came from the other
-	 * end of the bridge / tunnel or if we just entered the bridge / tunnel. */
-	if (AIBridge.IsBridgeTile(new_tile)) {
-		if (AIBridge.GetOtherBridgeEnd(new_tile) != prev_tile) return path.GetCost() + self._cost_tile;
-		return path.GetCost() + AIMap.DistanceManhattan(new_tile, prev_tile) * self._cost_tile + self._GetBridgeNumSlopes(new_tile, prev_tile) * self._cost_slope;
-	}
-	if (AITunnel.IsTunnelTile(new_tile)) {
-		if (AITunnel.GetOtherTunnelEnd(new_tile) != prev_tile) return path.GetCost() + self._cost_tile;
-		return path.GetCost() + AIMap.DistanceManhattan(new_tile, prev_tile) * self._cost_tile;
-	}
-
-	/* If the two tiles are more then 1 tile apart, the pathfinder wants a bridge or tunnel
-	 * to be build. It isn't an existing bridge / tunnel, as that case is already handled. */
-	if (AIMap.DistanceManhattan(new_tile, prev_tile) > 1) {
-		/* Check if we should build a bridge or a tunnel. */
-		if (AITunnel.GetOtherTunnelEnd(new_tile) == prev_tile) {
-			return path.GetCost() + AIMap.DistanceManhattan(new_tile, prev_tile) * (self._cost_tile + self._cost_tunnel_per_tile);
-		} else {
-			return path.GetCost() + AIMap.DistanceManhattan(new_tile, prev_tile) * (self._cost_tile + self._cost_bridge_per_tile) + self._GetBridgeNumSlopes(new_tile, prev_tile) * self._cost_slope;
-		}
-	}
-
-	/* Check for a turn. We do this by substracting the TileID of the current node from
-	 * the TileID of the previous node and comparing that to the difference between the
-	 * previous node and the node before that. */
-	local cost = self._cost_tile;
-	if (path.GetParent() != null && (prev_tile - path.GetParent().GetTile()) != (new_tile - prev_tile) &&
-		AIMap.DistanceManhattan(path.GetParent().GetTile(), prev_tile) == 1) {
-		cost += self._cost_turn;
-	}
-
-	/* Check if the new tile is a coast tile. */
-	if (AITile.IsCoastTile(new_tile)) {
-		cost += self._cost_coast;
-	}
-
-	/* Check if the last tile was sloped. */
-	if (path.GetParent() != null && !AIBridge.IsBridgeTile(prev_tile) && !AITunnel.IsTunnelTile(prev_tile) &&
-	    self._IsSlopedRoad(path.GetParent().GetTile(), prev_tile, new_tile)) {
-		cost += self._cost_slope;
-	}
-
-	if (!AIRoad.AreRoadTilesConnected(prev_tile, new_tile)) {
-		cost += self._cost_no_existing_road;
-	}
-
-	return path.GetCost() + cost;
-}
-
-function Road::_Estimate(cur_tile, cur_direction, goal_tiles, self)
-{
-	local min_cost = self._max_cost;
-	/* As estimate we multiply the lowest possible cost for a single tile with
-	 * with the minimum number of tiles we need to traverse. */
-	foreach (tile in goal_tiles) {
-		min_cost = min(AIMap.DistanceManhattan(cur_tile, tile) * self._cost_tile, min_cost);
-	}
-	return min_cost;
-}
-
-function Road::_Neighbours(path, cur_node, self)
-{
-	/* self._max_cost is the maximum path cost, if we go over it, the path isn't valid. */
-	if (path.GetCost() >= self._max_cost) return [];
-	local tiles = [];
-
-	/* Check if the current tile is part of a bridge or tunnel. */
-	if ((AIBridge.IsBridgeTile(cur_node) || AITunnel.IsTunnelTile(cur_node)) &&
-	     AITile.HasTransportType(cur_node, AITile.TRANSPORT_ROAD)) {
-		local other_end = AIBridge.IsBridgeTile(cur_node) ? AIBridge.GetOtherBridgeEnd(cur_node) : AITunnel.GetOtherTunnelEnd(cur_node);
-		local next_tile = cur_node + (cur_node - other_end) / AIMap.DistanceManhattan(cur_node, other_end);
-		if (AIRoad.AreRoadTilesConnected(cur_node, next_tile) || AITile.IsBuildable(next_tile) || AIRoad.IsRoadTile(next_tile)) {
-			tiles.push([next_tile, self._GetDirection(cur_node, next_tile, false)]);
-		}
-		/* The other end of the bridge / tunnel is a neighbour. */
-		tiles.push([other_end, self._GetDirection(next_tile, cur_node, true) << 4]);
-	} else if (path.GetParent() != null && AIMap.DistanceManhattan(cur_node, path.GetParent().GetTile()) > 1) {
-		local other_end = path.GetParent().GetTile();
-		local next_tile = cur_node + (cur_node - other_end) / AIMap.DistanceManhattan(cur_node, other_end);
-		if (AIRoad.AreRoadTilesConnected(cur_node, next_tile) || AIRoad.BuildRoad(cur_node, next_tile)) {
-			tiles.push([next_tile, self._GetDirection(cur_node, next_tile, false)]);
-		}
-	} else {
-		local offsets = [AIMap.GetTileIndex(0, 1), AIMap.GetTileIndex(0, -1),
-		                 AIMap.GetTileIndex(1, 0), AIMap.GetTileIndex(-1, 0)];
-		/* Check all tiles adjacent to the current tile. */
-		foreach (offset in offsets) {
-			local next_tile = cur_node + offset;
-			/* We add them to the to the neighbours-list if one of the following applies:
-			 * 1) There already is a connections between the current tile and the next tile.
-			 * 2) We can build a road to the next tile.
-			 * 3) The next tile is the entrance of a tunnel / bridge in the correct direction. */
-			if (AIRoad.AreRoadTilesConnected(cur_node, next_tile)) {
-				tiles.push([next_tile, self._GetDirection(cur_node, next_tile, false)]);
-			} else if ((AITile.IsBuildable(next_tile) || AIRoad.IsRoadTile(next_tile)) &&
-					(path.GetParent() == null || AIRoad.CanBuildConnectedRoadPartsHere(cur_node, path.GetParent().GetTile(), next_tile)) &&
-					AIRoad.BuildRoad(cur_node, next_tile)) {
-				tiles.push([next_tile, self._GetDirection(cur_node, next_tile, false)]);
-			} else if (self._CheckTunnelBridge(cur_node, next_tile)) {
-				tiles.push([next_tile, self._GetDirection(cur_node, next_tile, false)]);
-			}
-		}
-		if (path.GetParent() != null) {
-			local bridges = self._GetTunnelsBridges(path.GetParent().GetTile(), cur_node, self._GetDirection(path.GetParent().GetTile(), cur_node, true) << 4);
-			foreach (tile in bridges) {
-				tiles.push(tile);
-			}
-		}
-	}
-	return tiles;
-}
-
-function Road::_CheckDirection(tile, existing_direction, new_direction, self)
-{
-	return false;
-}
-
-function Road::_GetDirection(from, to, is_bridge)
-{
-	if (!is_bridge && AITile.GetSlope(to) == AITile.SLOPE_FLAT) return 0xFF;
-	if (from - to == 1) return 1;
-	if (from - to == -1) return 2;
-	if (from - to == AIMap.GetMapSizeX()) return 4;
-	if (from - to == -AIMap.GetMapSizeX()) return 8;
-}
-
-/**
- * Get a list of all bridges and tunnels that can be build from the
- * current tile. Bridges will only be build starting on non-flat tiles
- * for performance reasons. Tunnels will only be build if no terraforming
- * is needed on both ends.
- */
-function Road::_GetTunnelsBridges(last_node, cur_node, bridge_dir)
-{
-	local slope = AITile.GetSlope(cur_node);
-	if (slope == AITile.SLOPE_FLAT) return [];
-	local tiles = [];
-
-	for (local i = 2; i < this._max_bridge_length; i++) {
-		local bridge_list = AIBridgeList_Length(i + 1);
-		local target = cur_node + i * (cur_node - last_node);
-		if (!bridge_list.IsEmpty() && AIBridge.BuildBridge(AIVehicle.VT_ROAD, bridge_list.Begin(), cur_node, target)) {
-			tiles.push([target, bridge_dir]);
-		}
-	}
-
-	if (slope != AITile.SLOPE_SW && slope != AITile.SLOPE_NW && slope != AITile.SLOPE_SE && slope != AITile.SLOPE_NE) return tiles;
-	local other_tunnel_end = AITunnel.GetOtherTunnelEnd(cur_node);
-	if (!AIMap.IsValidTile(other_tunnel_end)) return tiles;
-
-	local tunnel_length = AIMap.DistanceManhattan(cur_node, other_tunnel_end);
-	local prev_tile = cur_node + (cur_node - other_tunnel_end) / tunnel_length;
-	if (AITunnel.GetOtherTunnelEnd(other_tunnel_end) == cur_node && tunnel_length >= 2 &&
-			prev_tile == last_node && tunnel_length < _max_tunnel_length && AITunnel.BuildTunnel(AIVehicle.VT_ROAD, cur_node)) {
-		tiles.push([other_tunnel_end, bridge_dir]);
-	}
-	return tiles;
-}
-
-function Road::_IsSlopedRoad(start, middle, end)
-{
-	local NW = 0; //Set to true if we want to build a road to / from the north-west
-	local NE = 0; //Set to true if we want to build a road to / from the north-east
-	local SW = 0; //Set to true if we want to build a road to / from the south-west
-	local SE = 0; //Set to true if we want to build a road to / from the south-east
-
-	if (middle - AIMap.GetMapSizeX() == start || middle - AIMap.GetMapSizeX() == end) NW = 1;
-	if (middle - 1 == start || middle - 1 == end) NE = 1;
-	if (middle + AIMap.GetMapSizeX() == start || middle + AIMap.GetMapSizeX() == end) SE = 1;
-	if (middle + 1 == start || middle + 1 == end) SW = 1;
-
-	/* If there is a turn in the current tile, it can't be sloped. */
-	if ((NW || SE) && (NE || SW)) return false;
-
-	local slope = AITile.GetSlope(middle);
-	/* A road on a steep slope is always sloped. */
-	if (AITile.IsSteepSlope(slope)) return true;
-
-	/* If only one corner is raised, the road is sloped. */
-	if (slope == AITile.SLOPE_N || slope == AITile.SLOPE_W) return true;
-	if (slope == AITile.SLOPE_S || slope == AITile.SLOPE_E) return true;
-
-	if (NW && (slope == AITile.SLOPE_NW || slope == AITile.SLOPE_SE)) return true;
-	if (NE && (slope == AITile.SLOPE_NE || slope == AITile.SLOPE_SW)) return true;
-
-	return false;
-}
-
-function Road::_CheckTunnelBridge(current_tile, new_tile)
-{
-	if (!AIBridge.IsBridgeTile(new_tile) && !AITunnel.IsTunnelTile(new_tile)) return false;
-	local dir = new_tile - current_tile;
-	local other_end = AIBridge.IsBridgeTile(new_tile) ? AIBridge.GetOtherBridgeEnd(new_tile) : AITunnel.GetOtherTunnelEnd(new_tile);
-	local dir2 = other_end - new_tile;
-	if ((dir < 0 && dir2 > 0) || (dir > 0 && dir2 < 0)) return false;
-	dir = abs(dir);
-	dir2 = abs(dir2);
-	if ((dir >= AIMap.GetMapSizeX() && dir2 < AIMap.GetMapSizeX()) ||
-	    (dir < AIMap.GetMapSizeX() && dir2 >= AIMap.GetMapSizeX())) return false;
-
-	return true;
-}
diff --git a/bin/ai/library/queue/binary_heap/library.nut b/bin/ai/library/queue/binary_heap/library.nut
deleted file mode 100644
index 5216fb588..000000000
--- a/bin/ai/library/queue/binary_heap/library.nut
+++ /dev/null
@@ -1,14 +0,0 @@
-/* $Id$ */
-
-class Binary_Heap extends AILibrary {
-	function GetAuthor()      { return "OpenTTD NoAI Developers Team"; }
-	function GetName()        { return "Binary Heap"; }
-	function GetShortName()   { return "QUBH"; }
-	function GetDescription() { return "An implementation of a Binary Heap"; }
-	function GetVersion()     { return 1; }
-	function GetDate()        { return "2008-06-10"; }
-	function CreateInstance() { return "Binary_Heap"; }
-	function GetCategory()    { return "Queue"; }
-}
-
-RegisterLibrary(Binary_Heap());
diff --git a/bin/ai/library/queue/binary_heap/main.nut b/bin/ai/library/queue/binary_heap/main.nut
deleted file mode 100644
index 05fd452f3..000000000
--- a/bin/ai/library/queue/binary_heap/main.nut
+++ /dev/null
@@ -1,131 +0,0 @@
-/* $Id$ */
-
-/**
- * Binary Heap.
- *  Peek and Pop always return the current lowest value in the list.
- *  Sort is done on insertion and on deletion.
- */
-class Binary_Heap
-{
-	_queue = null;
-	_count = 0;
-
-	constructor()
-	{
-		_queue = [];
-	}
-
-	/**
-	 * Insert a new entry in the list.
-	 *  The complexity of this operation is O(ln n).
-	 * @param item The item to add to the list.
-	 * @param priority The priority this item has.
-	 */
-	function Insert(item, priority);
-
-	/**
-	 * Pop the first entry of the list.
-	 *  This is always the item with the lowest priority.
-	 *  The complexity of this operation is O(ln n).
-	 * @return The item of the entry with the lowest priority.
-	 */
-	function Pop();
-
-	/**
-	 * Peek the first entry of the list.
-	 *  This is always the item with the lowest priority.
-	 *  The complexity of this operation is O(1).
-	 * @return The item of the entry with the lowest priority.
-	 */
-	function Peek();
-
-	/**
-	 * Get the amount of current items in the list.
-	 *  The complexity of this operation is O(1).
-	 * @return The amount of items currently in the list.
-	 */
-	function Count();
-
-	/**
-	 * Check if an item exists in the list.
-	 *  The complexity of this operation is O(n).
-	 * @param item The item to check for.
-	 * @return True if the item is already in the list.
-	 */
-	function Exists(item);
-};
-
-function Binary_Heap::Insert(item, priority)
-{
-	/* Append dummy entry */
-	_queue.append(0);
-	_count++;
-
-	local hole;
-	/* Find the point of insertion */
-	for (hole = _count - 1; hole > 0 && priority <= _queue[hole / 2][1]; hole /= 2)
-		_queue[hole] = _queue[hole / 2];
-	/* Insert new pair */
-	_queue[hole] = [item, priority];
-
-	return true;
-}
-
-function Binary_Heap::Pop()
-{
-	if (_count == 0) return null;
-
-	local node = _queue[0];
-	/* Remove the item from the list by putting the last value on top */
-	_queue[0] = _queue[_count - 1];
-	_queue.pop();
-	_count--;
-	/* Bubble down the last value to correct the tree again */
-	_BubbleDown();
-
-	return node[0];
-}
-
-function Binary_Heap::Peek()
-{
-	if (_count == 0) return null;
-
-	return _queue[0][0];
-}
-
-function Binary_Heap::Count()
-{
-	return _count;
-}
-
-function Binary_Heap::Exists(item)
-{
-	/* Brute-force find the item (there is no faster way, as we don't have the priority number) */
-	foreach (node in _queue) {
-		if (node[0] == item) return true;
-	}
-
-	return false;
-}
-
-
-
-function Binary_Heap::_BubbleDown()
-{
-	if (_count == 0) return;
-
-	local hole = 1;
-	local tmp = _queue[0];
-
-	/* Start switching parent and child until the tree is restored */
-	while (hole * 2 < _count + 1) {
-		local child = hole * 2;
-		if (child != _count && _queue[child][1] <= _queue[child - 1][1]) child++;
-		if (_queue[child - 1][1] > tmp[1]) break;
-
-		_queue[hole - 1] = _queue[child - 1];
-		hole = child;
-	}
-	/* The top value is now at his new place */
-	_queue[hole - 1] = tmp;
-}
diff --git a/bin/ai/library/queue/fibonacci_heap/library.nut b/bin/ai/library/queue/fibonacci_heap/library.nut
deleted file mode 100644
index 6cbd614da..000000000
--- a/bin/ai/library/queue/fibonacci_heap/library.nut
+++ /dev/null
@@ -1,14 +0,0 @@
-/* $Id$ */
-
-class Fibonacci_Heap extends AILibrary {
-	function GetAuthor()      { return "OpenTTD NoAI Developers Team"; }
-	function GetName()        { return "Fibonacci Heap"; }
-	function GetShortName()   { return "QUFH"; }
-	function GetDescription() { return "An implementation of a Fibonacci Heap"; }
-	function GetVersion()     { return 1; }
-	function GetDate()        { return "2008-08-22"; }
-	function CreateInstance() { return "Fibonacci_Heap"; }
-	function GetCategory()    { return "Queue"; }
-}
-
-RegisterLibrary(Fibonacci_Heap());
diff --git a/bin/ai/library/queue/fibonacci_heap/main.nut b/bin/ai/library/queue/fibonacci_heap/main.nut
deleted file mode 100644
index 6be8bdd49..000000000
--- a/bin/ai/library/queue/fibonacci_heap/main.nut
+++ /dev/null
@@ -1,204 +0,0 @@
-/* $Id$ */
-
-/**
- * Fibonacci heap.
- *  This heap is heavily optimized for the Insert and Pop functions.
- *  Peek and Pop always return the current lowest value in the list.
- *  Insert is implemented as a lazy insert, as it will simply add the new
- *  node to the root list. Sort is done on every Pop operation.
- */
-class Fibonacci_Heap {
-	_min = null;
-	_min_index = 0;
-	_min_priority = 0;
-	_count = 0;
-	_root_list = null;
-
-	/**
-	 * Create a new fibonacci heap.
-	 * http://en.wikipedia.org/wiki/Fibonacci_heap
-	 */
-	constructor() {
-		_count = 0;
-		_min = Node();
-		_min.priority = 0x7FFFFFFF;
-		_min_index = 0;
-		_min_priority = 0x7FFFFFFF;
-		_root_list = [];
-	}
-
-	/**
-	 * Insert a new entry in the heap.
-	 *  The complexity of this operation is O(1).
-	 * @param item The item to add to the list.
-	 * @param priority The priority this item has.
-	 */
-	function Insert(item, priority);
-
-	/**
-	 * Pop the first entry of the list.
-	 *  This is always the item with the lowest priority.
-	 *  The complexity of this operation is O(ln n).
-	 * @return The item of the entry with the lowest priority.
-	 */
-	function Pop();
-
-	/**
-	 * Peek the first entry of the list.
-	 *  This is always the item with the lowest priority.
-	 *  The complexity of this operation is O(1).
-	 * @return The item of the entry with the lowest priority.
-	 */
-	function Peek();
-
-	/**
-	 * Get the amount of current items in the list.
-	 *  The complexity of this operation is O(1).
-	 * @return The amount of items currently in the list.
-	 */
-	function Count();
-
-	/**
-	 * Check if an item exists in the list.
-	 *  The complexity of this operation is O(n).
-	 * @param item The item to check for.
-	 * @return True if the item is already in the list.
-	 */
-	function Exists(item);
-};
-
-function Fibonacci_Heap::Insert(item, priority) {
-	/* Create a new node instance to add to the heap. */
-	local node = Node();
-	/* Changing params is faster than using constructor values */
-	node.item = item;
-	node.priority = priority;
-
-	/* Update the reference to the minimum node if this node has a
-	 * smaller priority. */
-	if (_min_priority > priority) {
-		_min = node;
-		_min_index = _root_list.len();
-		_min_priority = priority;
-	}
-
-	_root_list.append(node);
-	_count++;
-}
-
-function Fibonacci_Heap::Pop() {
-
-	if (_count == 0) return null;
-
-	/* Bring variables from the class scope to this scope explicitly to
-	 * optimize variable lookups by Squirrel. */
-	local z = _min;
-	local tmp_root_list = _root_list;
-
-	/* If there are any children, bring them all to the root level. */
-	tmp_root_list.extend(z.child);
-
-	/* Remove the minimum node from the rootList. */
-	tmp_root_list.remove(_min_index);
-	local root_cache = {};
-
-	/* Now we decrease the number of nodes on the root level by
-	 * merging nodes which have the same degree. The node with
-	 * the lowest priority value will become the parent. */
-	foreach(x in tmp_root_list) {
-		local y;
-
-		/* See if we encountered a node with the same degree already. */
-		while (y = root_cache.rawdelete(x.degree)) {
-			/* Check the priorities. */
-			if (x.priority > y.priority) {
-				local tmp = x;
-				x = y;
-				y = tmp;
-			}
-
-			/* Make y a child of x. */
-			x.child.append(y);
-			x.degree++;
-		}
-
-		root_cache[x.degree] <- x;
-	}
-
-	/* The root_cache contains all the nodes which will form the
-	 *  new rootList. We reset the priority to the maximum number
-	 *  for a 32 signed integer to find a new minumum. */
-	tmp_root_list.resize(root_cache.len());
-	local i = 0;
-	local tmp_min_priority = 0x7FFFFFFF;
-
-	/* Now we need to find the new minimum among the root nodes. */
-	foreach (val in root_cache) {
-		if (val.priority < tmp_min_priority) {
-			_min = val;
-			_min_index = i;
-			tmp_min_priority = val.priority;
-		}
-
-		tmp_root_list[i++] = val;
-	}
-
-	/* Update global variables. */
-	_min_priority = tmp_min_priority;
-
-	_count--;
-	return z.item;
-}
-
-function Fibonacci_Heap::Peek() {
-	if (_count == 0) return null;
-	return _min.item;
-}
-
-function Fibonacci_Heap::Count() {
-	return _count;
-}
-
-function Fibonacci_Heap::Exists(item) {
-	return ExistsIn(_root_list, item);
-}
-
-/**
- * Auxilary function to search through the whole heap.
- * @param list The list of nodes to look through.
- * @param item The item to search for.
- * @return True if the item is found, false otherwise.
- */
-function Fibonacci_Heap::ExistsIn(list, item) {
-
-	foreach (val in list) {
-		if (val.item == item) {
-			return true;
-		}
-
-		foreach (c in val.child) {
-			if (ExistsIn(c, item)) {
-				return true;
-			}
-		}
-	}
-
-	/* No luck, item doesn't exists in the tree rooted under list. */
-	return false;
-}
-
-/**
- * Basic class the fibonacci heap is composed of.
- */
-class Fibonacci_Heap.Node {
-	degree = null;
-	child = null;
-
-	item = null;
-	priority = null;
-
-	constructor() {
-		child = [];
-		degree = 0;
-	}
-};
diff --git a/bin/ai/library/queue/priority_queue/library.nut b/bin/ai/library/queue/priority_queue/library.nut
deleted file mode 100644
index 1559393ee..000000000
--- a/bin/ai/library/queue/priority_queue/library.nut
+++ /dev/null
@@ -1,14 +0,0 @@
-/* $Id$ */
-
-class Priority_Queue extends AILibrary {
-	function GetAuthor()      { return "OpenTTD NoAI Developers Team"; }
-	function GetName()        { return "Priority Queue"; }
-	function GetShortName()   { return "QUPQ"; }
-	function GetDescription() { return "An implementation of a Priority Queue"; }
-	function GetVersion()     { return 2; }
-	function GetDate()        { return "2008-06-10"; }
-	function CreateInstance() { return "Priority_Queue"; }
-	function GetCategory()    { return "Queue"; }
-}
-
-RegisterLibrary(Priority_Queue());
diff --git a/bin/ai/library/queue/priority_queue/main.nut b/bin/ai/library/queue/priority_queue/main.nut
deleted file mode 100644
index feda89559..000000000
--- a/bin/ai/library/queue/priority_queue/main.nut
+++ /dev/null
@@ -1,115 +0,0 @@
-/* $Id$ */
-
-/**
- * Priority Queue.
- *  Peek and Pop always return the current lowest value in the list.
- *  Sort is done on insertion only.
- */
-class Priority_Queue
-{
-	_queue = null;
-	_count = 0;
-
-	constructor()
-	{
-		_count = 0;
-		_queue = [];
-	}
-
-	/**
-	 * Insert a new entry in the list.
-	 *  The complexity of this operation is O(n).
-	 * @param item The item to add to the list.
-	 * @param priority The priority this item has.
-	 */
-	function Insert(item, priority);
-
-	/**
-	 * Pop the first entry of the list.
-	 *  This is always the item with the lowest priority.
-	 *  The complexity of this operation is O(1).
-	 * @return The item of the entry with the lowest priority.
-	 */
-	function Pop();
-
-	/**
-	 * Peek the first entry of the list.
-	 *  This is always the item with the lowest priority.
-	 *  The complexity of this operation is O(1).
-	 * @return The item of the entry with the lowest priority.
-	 */
-	function Peek();
-
-	/**
-	 * Get the amount of current items in the list.
-	 *  The complexity of this operation is O(1).
-	 * @return The amount of items currently in the list.
-	 */
-	function Count();
-
-	/**
-	 * Check if an item exists in the list.
-	 *  The complexity of this operation is O(n).
-	 * @param item The item to check for.
-	 * @return True if the item is already in the list.
-	 */
-	function Exists(item);
-};
-
-function Priority_Queue::Insert(item, priority)
-{
-	/* Append dummy entry */
-	_queue.append(0);
-	_count++;
-
-	local i;
-	/* Find the point of insertion */
-	for (i = _count - 2; i >= 0; i--) {
-		if (priority > _queue[i][1]) {
-			/* All items bigger move one place to the right */
-			_queue[i + 1] = _queue[i];
-		} else if (item == _queue[i][0]) {
-			/* Same item, ignore insertion */
-			return false;
-		} else {
-			/* Found place to insert at */
-			break;
-		}
-	}
-	/* Insert new pair */
-	_queue[i + 1] = [item, priority];
-
-	return true;
-}
-
-function Priority_Queue::Pop()
-{
-	if (_count == 0) return null;
-
-	local node = _queue.pop();
-	_count--;
-
-	return node[0];
-}
-
-function Priority_Queue::Peek()
-{
-	if (_count == 0) return null;
-
-	return _queue[_count - 1][0];
-}
-
-function Priority_Queue::Count()
-{
-	return _count;
-}
-
-function Priority_Queue::Exists(item)
-{
-	/* Brute-force find the item (there is no faster way, as we don't have the priority number) */
-	foreach (node in _queue) {
-		if (node[0] == item) return true;
-	}
-
-	return false;
-}